▎ 摘　　要

NOVELTY - Development of aluminum/bauxite residue particulate metal matrix composite using a machine learning approach involves melting 1.2 kg base matrix and heating at 800 plus minus 5 degrees C in a nonstick coated mild steel sleeve under an inert environment, introducing a high ultra-pure 99.9% argon gas with 10 kg/minutes flow rate during fabrication, introducing 1.5 wt.% degassing agent hexachloroethane after melting of the base matrix to take out oxide gasses from the melt, mixing degasser in the melt by a stirrer at 300 rpm for 30 seconds, removing the dross from a surface and dipping 1 wt.% magnesium wrapped in aluminum foil paper to induce wettability with BR particles, restricting magnesium to float on the surface of melt by holding magnesium through a zirconium coated rod into the melt for 20 seconds, restricting contamination with melt and particles upon mixing through a mechanical stirrer with zircon coating. USE - Method for development of aluminum/bauxite residue particulate metal matrix composite using machine learning approach. ADVANTAGE - The method has environment-friendly, and slurry blending and graphene oxide reduction has simple, efficient, and has easy for large-scale production. DETAILED DESCRIPTION - Development of aluminum/bauxite residue particulate metal matrix composite using machine learning approach involves melting 1.2 kg base matrix and heating at 800 plus minus 5 degrees C in a nonstick coated mild steel sleeve under an inert environment, introducing a high ultra-pure 99.9% argon gas with 10 kg/minutes flow rate during fabrication, introducing 1.5 wt.% degassing agent hexachloroethane after melting of the base matrix to take out oxide gasses from the melt, mixing degasser in the melt by a stirrer at 300 rpm for 30 seconds, removing the dross from a surface and dipping 1 wt.% magnesium wrapped in aluminum foil paper to induce wettability with BR particles, restricting magnesium to float on the surface of melt by holding magnesium through a zirconium coated rod into the melt for 20 seconds, restricting contamination with melt and particles upon mixing through a mechanical stirrer with zircon coating, introducing preheat BR particles for 2 hours with 3.5 g/minutes feed rate into a vortex formed by the stirrer, and pouring in a metallic mold in vacuum environment in preheated permanent metallic match piece plate mold.